Local quenches, bulk entanglement entropy and a unitary Page curve

Abstract: Quantum corrections to the entanglement entropy of matter fields interacting with dynamical gravity have proven to be very important in the study of the black hole information problem. We consider a one-particle excited state of a massive scalar field infalling in a pure AdS3 geometry and compute these corrections for bulk subregions anchored on the AdS boundary. In the dual CFT2, the state is given by the insertion of a local primary operator and its evolution thereafter. We calculate the area and bulk entang… Show more

“…Remarkably, we can reach the same conclusion from the plots in figure 7, which exhibit the following features: i) two wave packets moving together with the shocks, i.e., in opposite directions at the speed of light and ii) threads around each wave packet connecting degrees of freedom in their fronts with those in their tails. The fact that we do not see threads connecting the two wave packets implies that they are effectively unentangled at the leading order in G N , in agreement with the result of [74]. Moreover, the precise pattern of the threads explains why S A peaks at t = R (see e.g.…”

“…In [73] it was conjectured that the quench insertion generates an entangled pair of wave packets that move in opposite directions (see figure 4 of [73] for a pictorial representation). However, it was recently shown in [74] that this intuition is only true if one includes the leading JHEP01(2021)193 1/N corrections coming from the entanglement of bulk fields. More specifically, in this paper it was argued that at the leading order in G N the two wave packets are effectively unentangled, and only the quantum correlations between the degrees of freedom in each individual packet contribute to the total entanglement entropy.…”

“…Moreover, the precise pattern of the threads explains why S A peaks at t = R (see e.g. figure 7 of [74]): at this time most of the threads connect the degrees of freedom of A with those in its complement (recall that threads connecting points within A do not contribute to the entanglement entropy of the region). It will be very interesting to repeat this analysis for the case of a global quench, and understand how the local pattern of entanglement evolves in time for cases that admit an entanglement tsunami interpretation [75,76] (large regions) and cases that do not [77,78] (small regions).…”

“…However, for concreteness we will consider an example that is physically motivated: a local quench that arises by the insertion of a local primary operator. The stress tensor of a local quench is given by the sum of two shock waves [73,74],…”

Bit threads, Einstein’s equations and bulk locality

“…Remarkably, we can reach the same conclusion from the plots in figure 7, which exhibit the following features: i) two wave packets moving together with the shocks, i.e., in opposite directions at the speed of light and ii) threads around each wave packet connecting degrees of freedom in their fronts with those in their tails. The fact that we do not see threads connecting the two wave packets implies that they are effectively unentangled at the leading order in G N , in agreement with the result of [74]. Moreover, the precise pattern of the threads explains why S A peaks at t = R (see e.g.…”

“…In [73] it was conjectured that the quench insertion generates an entangled pair of wave packets that move in opposite directions (see figure 4 of [73] for a pictorial representation). However, it was recently shown in [74] that this intuition is only true if one includes the leading JHEP01(2021)193 1/N corrections coming from the entanglement of bulk fields. More specifically, in this paper it was argued that at the leading order in G N the two wave packets are effectively unentangled, and only the quantum correlations between the degrees of freedom in each individual packet contribute to the total entanglement entropy.…”

“…Moreover, the precise pattern of the threads explains why S A peaks at t = R (see e.g. figure 7 of [74]): at this time most of the threads connect the degrees of freedom of A with those in its complement (recall that threads connecting points within A do not contribute to the entanglement entropy of the region). It will be very interesting to repeat this analysis for the case of a global quench, and understand how the local pattern of entanglement evolves in time for cases that admit an entanglement tsunami interpretation [75,76] (large regions) and cases that do not [77,78] (small regions).…”

“…However, for concreteness we will consider an example that is physically motivated: a local quench that arises by the insertion of a local primary operator. The stress tensor of a local quench is given by the sum of two shock waves [73,74],…”

Bit threads, Einstein’s equations and bulk locality

“…The bulk first law has already been extended to this semiclassical regime in [29], but for future work it would be especially interesting to find the dual CFT first law including leading order 1/c corrections for perturbative excited states (see e.g. [123,124]).…”

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